Purpose : :
This study aimed to highlight structural corneal changes in a model of type 2 diabetes, using in vivo corneal confocal microscopy (CCM). The abnormalities were also characterized by transmission electron microscopy (TEM) and second harmonic generation (SHG) microscopy in rat and human corneas.

Methods : :
Goto-Kakizaki (GK) rats were observed at age 12 weeks (n = 3) and 1 year (n = 6), and compared to age-matched controls. After in vivo CCM examination, TEM and SHG microscopy were used to characterize the ultrastructure and the three-dimensional organization of the abnormalities. Human corneas from diabetic (n = 3) and nondiabetic (n = 3) patients were also included in the study.

Results : :
In the basal epithelium of GK rats, CCM revealed focal hyper-reflective areas, and histology showed proliferative cells with irregular basement membrane. In the anterior stroma, extracellular matrix modifications were detected by CCM and confirmed in histology. In the Descemet's membrane periphery of all the diabetic corneas, hyper-reflective deposits were highlighted using CCM and characterized as long-spacing collagen fibrils by TEM. SHG microscopy revealed these deposits with high contrast, allowing specific detection in diabetic human and rat corneas without preparation and characterization of their three-dimensional organization.

Conclusion : :
Pathologic findings were observed early in the development of diabetes in GK rats. Similar abnormalities have been found in corneas from diabetic patients.

Translational Relevance : :
This multidisciplinary study highlights diabetes-induced corneal abnormalities in an animal model, but also in diabetic donors. This could constitute a potential early marker for diagnosis of hyperglycemia-induced tissue changes.

Introduction

Chronic hyperglycemia resulting from poorly controlled diabetes leads to tissue modifications that are mainly induced by the reactive oxygen species-activated pathways.1 These molecular mechanisms precede, sometimes by years, clinically detectable complications of diabetes. Among these complications, diabetic retinopathy, which is a major cause of vision loss in the western population, is detected earliest by retinal microangiopathy. However, alterations of retinal functions have been shown to precede the first clinically detected signs of retinopathy.2 Obviously, any simple means of earlier diagnosis of hyperglycemia-induced tissue changes could help design new preventive treatments and protocols for eye care of diabetic patients, notably in order to define at-risk patients and to anticipate retinal deterioration. For this purpose, as diabetes is associated with a number of structural changes in the cornea, this transparent and easily accessible ocular tissue could provide a window to detect the earliest hyperglycemia-induced abnormalities.

For 20 years, as a result of the development of microscopic imaging systems such as transmission electron microscopy (TEM) and corneal confocal microscopy (CCM), and of the optimization of immunohistochemistry methods, hyperglycemia-induced modifications have been described in corneas of diabetic organisms, in both rat models and human beings. At the epithelium level, focal epithelial cell degeneration and morphologic alterations of the extracellular matrix,3–5 alteration of the epithelial barrier function,6,7 delay of corneal epithelial wound healing8,9 and non-enzymatic glycation of proteins by advanced glycation end-products (AGEs)10–14 have been reported. TEM observations have also highlighted the presence of unusual long-spacing collagen fibril aggregates among both stromal matrix and Descemet's membrane (DM) of corneas from diabetic patients5 and in the DM of diabetic rat models.15,16 Finally, diabetes may compromise the stromal hydration through a decrease in endothelial cell density17,18 and change in cell morphology.19,20 Taken all together these studies suggest that diabetes accelerates age-related molecular processes.

In this context, this study aimed to characterize corneal structural changes in a spontaneous rat model of type 2 diabetes and in human corneas from diabetic donors. For this purpose, three complementary imaging techniques were combined because they allowed imaging corneal structures with different contrast modes and scales. Observation of the abnormalities by in vivo CCM was complemented by histologic analysis, TEM, and second harmonic generation (SHG) microscopy. The last-mentioned technique is an emerging multiphoton method that reveals unstained collagen fibrils with unequalled contrast and specificity, so allows determining the spatial organization of fibrillar collagen structures with micrometric resolution.21–28 SHG microscopy was performed in intact ex vivo corneas. Histology and TEM were used in fixed, stained, and sliced tissues as gold standard methods with complementary resolutions in order to characterize the abnormal corneal ultrastructures.

In this study, we first highlighted structural changes in all the layers of the Goto-Kakizaki (GK) rat corneas using CCM and histology, mainly, structural abnormalities at the epithelium-stroma interface, signs of endothelial cells stress, and deposits of long-spacing fibrillar collagen in the DM. We then focused on the abnormal deposits highlighted in the DM using all the complementary microscopic methods. SHG microscopy notably allowed their specific detection in the corneas from GK rats but also from human diabetic donors. These findings will be presented in the following, and discussed in relationship to pathologic processes during diabetes.

Materials and Methods

Animals

All animals were treated in accordance with the ARVO Statement for the Use of Animals in Ophthalmic and Vision Research. Twelve-week-old (n = 3) and 1-year-old (n = 6) GK rats that spontaneously developed diabetes mellitus, from our facilities, were included and compared to age-matched nondiabetic rats from our facilities or purchased (Janvier; Le Genest-Saint-Isle, France) and roomed for 1 week before inclusion in the study. Rat data and performed analysis are given in Table 1.

Diabetic (a) and Control (b) Rats Data, Including Corneal In Vivo and Ex Vivo Analysis Performed

Table 1.

Diabetic (a) and Control (b) Rats Data, Including Corneal In Vivo and Ex Vivo Analysis Performed

Human Corneas

We obtained six human corneas assigned to scientific use,29 from an eye bank association (Banque Française des Yeux; Paris, France). Human corneas were used under informed consent of the relatives, according to French bioethics laws. The study was conducted according to the tenets of the Declaration of Helsinki for biomedical research involving human corneas. Mean donor age was 75 years (3 women, 3 men; age range, 60–83 years). As described in Table 2, three nondiabetic patients and three patients with type 2 diabetes were included. Corneas were excised with 16- to 18-mm-diameter trephination, and immediately stored in 100 mL organ culture medium (CorneaMax; Eurobio, Courtabœuf, France) at 31°C in a dry incubator until the experiment, at least 2 weeks later. Due to this storage, all corneas from both diabetic and nondiabetic donors were slightly edematous as demonstrated by their increased thickness (typically 700 to 900 μm) compared to physiologic corneal thickness (approximately 500 μm).

A confocal laser scanning system (Heidelberg Retina Tomograph II with Rostock Cornea Module [HRT II]; Heidelberg Engineering GmbH, Heidelberg, Germany) was used to examine the rat corneas as previously described.30 Before in vivo CCM examination, rats were anesthetized with a mixture of 50 mg/kg ketamine chlorhydrate (Kétamine 1000, Virbac; Carros, France) and 5 mg/kg xylasine (Rompun 2%, Bayer HealthCare AG; Puteaux, France), positioned on a special stage and immobilized to align the central cornea parallel to the objective front lens. A drop of gel tear substitute (Lacrigel, carbomer 0.2%; Europhta, Monaco, Principauté de Monaco) was placed on the objective front lens to maintain immersion contact between the objective and the cornea and to avoid corneal drying. To allow examination, the HRT II camera (Heidelberg Engineering GmbH) was disconnected from the headrest and maintained vertically. The laser source consisted of a 670 nm laser diode. The objective was an objective at x60 magnification and 0.90 numerical aperture (NA), covered by a polymethyl methacrylate cap. Images consisted of 384 × 384 pixels covering an area of 400 × 400 μm, which approximately corresponds to 1 μm/pixel with a pixel acquisition time of 0.024 seconds. Images were acquired using an automatic-gain mode. The x-y position and the depth of the optical section were controlled manually; the focus position in depth was automatically calculated by the microscope software.

Ex Vivo SHG Microscopy

The corneas of the oldest rats included in the study were examined using a custom-built laser scanning multiphoton microscope, as previously described,27,28 with detection of SHG signals. Excitation was performed using a titanium-sapphire laser (Tsunami; Spectra Physics, Newport Corporation, Irvine, CA). The setup incorporated detection channels in forward and backward directions with photon-counting modules (P25PC photomultiplier tubes; ET Enterprises Ltd, Uxbridge, UK).

For ex vivo imaging, the rat corneas were placed in Hanks medium immediately after their removal. All the corneas were flat mounted as follows: the buttons were gently transferred onto a first coverslip, three small incisions were cut at the periphery under operating binocular microscope in order to flatten the cornea curvature, and a drop of Hanks medium was added before putting the second coverslip. The coverslips were maintained in a custom-built sample holder adapted to the microscope stage. SHG imaging was performed at 860-nm excitation with circular incident polarization. Forward and backward SHG signals from collagen fibrils were detected at one-half the incident excitation wavelength with well-suited filters (FF01-427/10 interferential filter and 680SP rejection filters; Semrock, Lake Forest, IL). Large-scale images were generated using a water-immersion 20x, 0.95 NA objective (Olympus, Tokyo, Japan) with typically 2 μm axial × 0.4 μm lateral resolutions. High-resolution images were recorded using a water-immersion 60x,1.2 NA objective (Olympus) with 1 μm axial × 0.3 μm lateral resolutions. Image stacks were recorded with 0.5 to 1 μm lateral pixel size, and 0.5 to 2 μm axial steps. Laser power at the objective focus was typically 20 to 85 mW. Acquisition time was 3 to 5 μs per pixel (i.e., typically approximately 1 second for a 512 × 512 pixel image).

Ex vivo imaging of intact rat eyeballs was also performed using SHG. Just after enucleation, the examined eye was mounted in a molded agarose gel. Optical contact between the cornea and the immersion objective was maintained with a gel tear substitute (Lacrigel) and only backward SHG signals could be detected as in in vivo configuration.

Histology and Transmission Electron Microscopy

The corneas were fixed with 2.5% glutaraldehyde in cacodylate buffer (0.1 M, pH 7.4) and with 1% osmium tetroxyde in cacodylate buffer (0.2 M), and then subjected to successive dehydration in graduated ethanol solution (50, 70, 95, and 100%) and in propylene oxide. Each area of interest was separately included in epoxy resin and oriented. Semi-thin sections (1 μm) were obtained with an ultra microtome (OmU2; Reichert, Austria) and stained with toluidine blue. Ultra-thin sections (100 nm) were contrasted by uranyl acetate and lead citrate, and analyzed with a transmission electron microscope (TEM CM10, Philips; Eindhoven, The Netherlands) coupled with a CCD camera (ES1000W Erlangshen; Gatan, Évry, France).

Results

In Vivo Corneal Confocal Microscopy in Nondiabetic Rats

Figure 1 illustrates a non-diabetic rat cornea observed by CCM examinations, showing the light-scattering interfaces. In the transverse section (Fig. 1A), the epithelium presented a healthy structure composed of distinct epithelial layers with regular basal cells and thin superficial cells. Frontal sections (Fig. 1B) were generated in each corneal layer. The basal epithelium cells were visualized through the detection of the junctions between their lipid-rich membranes and their cytoplasm. Whereas Bowman's layer did not appear on histologic sections in the rats (Fig. 1C), in vivo CCM examination allowed the detection of an amorphous membrane with fine nerve plexi (Fig. 1B). In the stroma, CCM allowed the detection of the keratocytes. In the posterior cornea, the DM appeared amorphous and the hexagonal endothelial cells, with a 20 μm regular diameter, exhibited a honeycomb pattern.

During CCM examinations of the diabetic GK rats, abnormalities of reflectance were observed as early as 3 months of age. Main in vivo CCM patterns are summarized in Table 3.

In young as in old diabetic rats, hypersignals at the interface between the epithelium and the anterior stroma faded the normal signals from epithelial cell junctions in the transverse sections (Figs. 2A–B). In all the youngest GK rats' corneas (n = 3/3), the frontal sections revealed an irregular basal epithelium with focal areas composed of cells without distinct junctions and adjacent hyper-reflective borders (Fig. 2C). In the oldest diabetic rats' corneas (n = 6/6), focal hyper-reflective areas (Fig. 2D) were also detected at this level. At the Bowman's layer level, in young (n = 1/3) (Fig. 2E) as well as in old diabetic rats (n = 4/6) (Fig. 2F), hyper-reflective “swelling” was highlighted in corneal peripheries.

Main In Vivo Confocal Microscopy Patterns Observed in Corneas from Diabetic Rats

Table 3.

Main In Vivo Confocal Microscopy Patterns Observed in Corneas from Diabetic Rats

On histology, proliferative epithelial basal cells (Figs. 3E1–E2) were observed in the diabetic cases and the abnormal epithelium-stroma interface was confirmed. Whereas the center of the diabetic corneas demonstrated normal corneal histology at this level (Fig. 3A), changes in extracellular matrix organization were detected in corneal peripheries around activated keratocytes (Figs. 3E1–3E3). These keratocytes exhibit a bigger blue-stained intracellular compartment than the normal cells with elongated and thin nuclei (see Fig. S1). TEM confirmed that the anterior stroma matrix was organized differently in the center than in the periphery of diabetic corneas. In the corneal center, although the epithelial basal lamina appeared thickened with numerous invaginations (Fig. 3D) as already reported,4,5 collagen lamellae were normal (Figs. 3B–3C), similar to the lamellar organization in normal corneas. On the contrary, in the periphery of the diabetic corneas, the anterior lamellar structures showed abnormally tile-shaped accumulation of collagen fibrils with homogeneous diameter, surrounded by micro-fibrils and in contact with the basal lamina (Figs. 3F–3H, white arrowheads).

In human corneas from diabetic donors, histology of the anterior corneal layers demonstrated similar alterations of the epithelial basement membrane, but no change was detected in the extracellular matrix organization (not shown).

Endothelium and Descemet's Membrane of Diabetic Corneas

During CCM examination of the GK rats, abnormalities were detected in all the observed corneas, in both the endothelium and the DM (Table 4). Regarding the endothelium, different signs of cell stresses were highlighted. Hyper-reflective patterns were observed at the endothelial cell junctions as early as 3 months of age (n = 1/3) (Fig. 4A) and in the oldest GK rats (n = 4/6) in which other stress signs included endothelial dystrophy (n = 2/6) (Fig. 4B) and abnormal cell morphology (n = 1/6). Just above the endothelial cells, sparse hyper-reflective and rod-shaped structures were detected with high density in the DM periphery of the youngest (n = 3/3) (Fig. 4C) as in the oldest GK rats (n = 6/6) (Fig. 4D). In both corneas from one rat, these rod-shaped structures were detected in the entire DM surface. The same hyper-reflective bodies were also observed with a lesser extent in periphery of two corneas from old control rats (n = 2/6) (Fig. 4E).

Corneal changes in the posterior corneas of GK rats highlighted by in vivo CCM. (A–B) Frontal images of the endothelium, demonstrating signs of endothelial cell stresses, as hyper-reflective junctions in young GK rats (A) and cornea guttata (B) in old GK rats. (C–F) Frontal images of the DM, showing hyper-reflective dense deposits in corneal peripheries from both young (C) and old (D, F) GK rats. In old nondiabetic control rat, DM images showed no or sparse (E) hyper-reflective deposits. Scale bar, 100 μm.

Figure 4.

Corneal changes in the posterior corneas of GK rats highlighted by in vivo CCM. (A–B) Frontal images of the endothelium, demonstrating signs of endothelial cell stresses, as hyper-reflective junctions in young GK rats (A) and cornea guttata (B) in old GK rats. (C–F) Frontal images of the DM, showing hyper-reflective dense deposits in corneal peripheries from both young (C) and old (D, F) GK rats. In old nondiabetic control rat, DM images showed no or sparse (E) hyper-reflective deposits. Scale bar, 100 μm.

On histology, toluidine blue staining confirmed the presence of abnormal deposits in the DM posterior part of the diabetic corneas (Figs. 5A–5B) but did not allow identifying their composition. This was performed during TEM analysis that revealed the presence of long-spacing collagen fibrils at the same level (Figs. 5C–5D). In all the micrographs, these pathologic collagen fibrils were distributed in the posterior part of the DM, and some of them were observed just near the endothelial cells as illustrated in Figure 5C, suggesting their secretion by these cells.

We then used ex vivo SHG microscopy to probe specifically these pathologic collagen fibrils with a larger field of view than in TEM and to characterize their 3D distribution in the DM. In the normal human cornea, ex vivo SHG microscopy reflects the distribution of the type 1 collagen in the stroma, while the nonfibrillar collagen constituting the DM does not exhibit SHG signals.27 In the DM of the GK rat corneas, the hyper-reflective structures highlighted by in vivo CCM exhibited strong SHG signals, while, as expected, other regions of the DM showed no signal. Their SHG-pattern was the same as previously described. The structures had a weak density in two old control corneas (Fig. 6A) and were very dense in all diabetic cases (Fig. 6B). Moreover, acquisition of image stacks with 0.5 μm axial steps enabled 3D reconstruction of DM abnormalities with excellent contrast (Fig. 6C) (see Movie for 3D view). While SHG observations of flat-mounted corneas were performed using forward-detected SHG signals, the proof of feasibility of the abnormalities' detection from the epithelium was carried out in rat eyeballs. Figure 6D demonstrates that the structures in the DM of a diabetic rat cornea exhibited backward SHG signals with the same high contrast, allowing epidetection of these structures.

3D SHG view of the DM of the GK cornea No. 7 in false colors (200 × 200 × 9 μm3). Strong SHG signals are emitted by fibrillar collagen abnormalities, which allows their spatial characterization. Note that the fibrils in the foreground appear larger than in the background because of the 3D viewer.

Movie.

3D SHG view of the DM of the GK cornea No. 7 in false colors (200 × 200 × 9 μm3). Strong SHG signals are emitted by fibrillar collagen abnormalities, which allows their spatial characterization. Note that the fibrils in the foreground appear larger than in the background because of the 3D viewer.

Three human corneas from diabetic patients (No. 1–3) (see Table 2) were also analyzed using SHG microscopy and compared to corneas from nondiabetic donors (No. 4–6). Observations at the DM level are synthesized in Table 5. No signal (No. 6) (Fig. 7A) or sparse signs of aging (No. 5) were detected in the DM of the corneas from nondiabetic donors. In the corneas from the third nondiabetic donors, with arterial hypertension and dyslipedemia (No. 4), few structures exhibiting SHG signals were detected only in the DM periphery (Fig. 7B). In the diabetic cases, whereas these structures were observed in the entire DM of the corneas from patients with unbalanced diabetes (No. 1 and No. 2) (Figs. 7C–7D), they were found only in the corneal periphery of the patient with balanced diabetes (No. 3) (Figs. 7E–7F).

Ex vivo SHG images in the DM of human corneas. (A–B) False color images of the corneas from nondiabetic donors, showing sparse SHG signals in corneal periphery of one hypertensive patient (B, in green; 20x objective). (C–F) False color images of the corneas from two diabetic donors, demonstrating the presence of SHG signals (in green) in the entire DM in the case of unbalanced diabetes (C–D; 60x objective) and only in the DM periphery in the case of balanced diabetes (E–F; 20x objective). Scale bar, 20 μm.

Figure 7.

Ex vivo SHG images in the DM of human corneas. (A–B) False color images of the corneas from nondiabetic donors, showing sparse SHG signals in corneal periphery of one hypertensive patient (B, in green; 20x objective). (C–F) False color images of the corneas from two diabetic donors, demonstrating the presence of SHG signals (in green) in the entire DM in the case of unbalanced diabetes (C–D; 60x objective) and only in the DM periphery in the case of balanced diabetes (E–F; 20x objective). Scale bar, 20 μm.

Histologic and TEM analysis confirmed that these abnormalities were identical to those observed in the diabetic rat corneas. They displayed long-spacing collagen fibrils, located in the inner part of the DM (Figs. 8A–8C), and therefore most likely produced by endothelial cells (Figs. 8D–8E). Senescence of the donors' endothelial layers was also observed, as shown in Figures 8C–8F identifying corneal endothelial dystrophy with endothelial cell extensions and long-spacing collagen.

In the present study, in vivo CCM highlighted structural abnormalities in the entire corneal thickness of the GK model of type 2 diabetes. It confirms the potential of this noninvasive imaging modality as a diagnostic tool, as extensively studied for 5 years for diabetic neuropathy.31,32 For this purpose, in vivo CCM is currently used in both preclinical33 and clinical34 studies. The contrast mechanism of this system relies on spatial variations of refractive indices, like in light-scattering interfaces, as junctions between cytoplasm or extracellular fluid and lipid-rich membranes of cells, nucleus and mitochondria.35 CCM allows easy recognition of the corneal nerves and, so, the development of a new algorithm to perform image rebuilding of the sub-basal nerve plexus.36 However, confocal reflectance microscopy shows limited contrast and specificity to identify the structures responsible for the abnormal reflectance detected in the DM of the GK rat corneas.

To complement these in vivo CCM observations, TEM imaging revealed the nature of the long-spacing collagen deposits in the DM. Nevertheless, these classic methods require stained corneal sections and are long to carry out. As SHG microscopy allows specific detection of collagen fibrils in unstained tissues, this femtosecond laser-based technology was tested as a quickest alternative method. SHG is a multiphoton mode of contrast that appears at half of the excitation wavelength and is specific for dense non-centrosymmetric structures, such as collagen fibrils. In contrast, nonfibrillar collagen, such as type IV and type VIII collagen in the DM, exhibits no SHG signal because of its centrosymmetric organization. We, therefore, expected SHG to be a valuable tool to evidence fibrillar collagen deposits among nonfibrillar matrix. Accordingly, comparison between in vivo CCM images and ex vivo SHG images demonstrated that the hyper-reflective structures found in the DM of the GK rat corneas exhibited strong SHG signals, in both forward and backward directions, on a SHG silent background. These results showed that SHG microscopy could detect hyperglycemia-induced abnormalities with excellent contrast in GK corneas, as well as in human corneas from diabetic donors. Comparative imaging of corneas from hyperglycemic individuals therefore provided complementary information on DM structural changes. We noted that the long-spacing collagen fibrils in the DM were thinner than 1 μm in TEM images, while they appeared larger in CCM images because of the lower resolution (1 μm pixel size) and of the automatic contrast setting that impedes the detection of thin structures.

Backward-detected SHG imaging has been demonstrated in ex vivo ocular globes and could thus provide a diagnosis for chronic hyperglycemia-induced effects in the corneal tissue. First developments toward a clinical imaging system have been reported recently28 and showed that in vivo SHG imaging can generate quantitative information about the collagen architecture in the stroma. This femtosecond laser-based imaging system could thus provide additional diagnosis of structural abnormalities in the stroma, observed in other corneal pathologies.

From a pathophysiologic point of view, this study has highlighted focal abnormal reflectance in the basal epithelium of diabetic corneas that is a sign of diabetic keratopathy. On histology, numerous epithelial basal cells were in a proliferative state, as reported by Wakuta et al.l9 The increased proliferation of epithelial cells in the cornea of GK rats was demonstrated to be associated with a delay in wound healing and, thus, to affect the epithelial barrier function. These features were met again in the streptozotocin-induced model of type 1 diabetes,37 and in diabetic patients using the fluorescein test6 or in vivo CCM.8 The well-known epithelial basement membrane abnormality of diabetic corneas3–5 was also observed in our study, in both rat and human corneas. The increased reflectivity measured at the interface between the epithelial basal cell layer and the anterior stroma by Morishige et al39 and Takahashi et al40 could explain the hyper-reflectance detected on the CCM transverse images of the GK rat epitheliums generated in our experiments. From a biochemical point of view, the abnormalities noticed at the epithelium-stroma interface in the cornea of GK rats might reflect the chronic hyperglycemia-induced effects, in particular the Maillard reactions. These reactions result in the formation of AGEs, which are responsible for non-enzymatic glycation reactions on the extracellular matrix proteins. Their effects increase with aging41 and are amplified by diabetes.42 Increased protein glycations12–14 and oxidative stress43 are involved in diabetic cornea alterations, such as decreased stability in the epithelial basement membrane and changes in the collagen matrix of the anterior stroma. However, whether AGEs have cytotoxic effects mediated by the AGE receptors (RAGE) on corneal keratocytes remains to be studied.

Regarding the posterior layers of the diabetic corneas, various endothelial abnormalities, in particular endothelial dystrophy and abnormal cell morphology, were noticed in the corneas of the oldest GK rats. Corneal observations in diabetic patients using CCM or specular microscopy have actually shown that diabetes may disturb the stromal hydration through decreased endothelial cell density,17 in particular after cataract surgery,18 and polymegathism (changes in their size).19,20 The endothelium may thus be under greater metabolic stress in diabetic than in healthy subjects. Endothelial cells are known to be sensitive to AGEs44 and to express their receptors.45 Therefore, AGE formation may be responsible for non-enzymatic glycation, leading to endothelial cell loss,45 but also for the RAGE pathway activation. This may induce changes in gene expression in endothelial cells and, so, the abnormal secretion of long-spacing collagen in the DM of diabetic rat16,15 and human corneas.5 These pathologic collagen fibrils were detected as hyper-reflective and rod-shaped structures in the DM and in the endothelial cell junctions using in vivo CCM, and then, TEM which allowed imaging their synthesis by the endothelial cells. Blood sugar levels revealed the hyperglycemic state of the observed GK rats; however, they are not indicative of the metabolic effects of diabetes. For such a purpose, glycosylated hemoglobin (HbA1c) should be measured. Even if this indicator was not followed at the time of our experiments, the preliminary data currently measured in our facilities show that HbA1c levels start to increase before 3 months of age in GK rats in comparison with Wistar rats. Recent papers46,47 have also demonstrated that, whereas HbA1c slightly increased from 4 to 5% at 12 weeks and then reached a plateau in Wistar rats, HbA1c levels in GK rats showed a delayed increase relative to glucose at 4 weeks, and then gradually increased until the end of the studies, from 4 to 5%, to 9% at 12 weeks46 or to over 11% at 20 weeks of age.47 These data allowed us to state that the deposits observed in the DM at 12 weeks of age in GK rat corneas were synthesized as soon as the diabetes induced metabolic effects.

Moreover, these abnormalities were observed in human corneas from diabetic donors, with higher density in the cases of unbalanced diabetes, notably in the cornea from a patient with a HbA1c level over 9%, than in balanced diabetes, in the case of a donor with a normal HbA1c level. These collagen deposits have also been observed in the corneas from hypertensive old patients in our study, and reported in other endothelial pathologies, such as iridocorneal-endothelial syndrome48,49 and Fuch's dystrophy,48–51 in which AGEs accumulate as well as oxidative stress.52 Diabetes-induced tissue changes have been characterized as accelerated aging in many organs, and also in collagen changes.53 Our observations let us hypothesize that the abnormal collagen synthesis is an age-related phenomenon observed earlier and exacerbated in diabetic conditions and, probably, in other metabolic diseases inducing an oxidative stress on corneal endothelial cells.

To conclude, we have used complementary imaging techniques to demonstrate that diabetes alters the structure of all corneal layers. In diabetic rat corneas, we have mainly highlighted structural abnormalities at the epithelium-stroma interface and fibrillar collagen deposits in the DM. This latter feature has also been observed and characterized in human corneas using SHG microscopy, and confirmed by TEM. Subclinical abnormalities could predispose diabetic patients to wound healing delay and also serve as early signs of diabetes-induced tissue structure modifications. Our observations in the DM demonstrated that diabetes altered the collagen structure of this layer, with the formation of long-spacing collagen fibrils synthesized by corneal endothelial cells. Whether these changes could be correlated to blood–sugar-level control remains to be demonstrated. Moreover, we have shown that SHG microscopy, an emerging multiphoton imaging method that is highly specific for collagen fibrils, could provide a diagnosis for chronic hyperglycemia-induced effects in the corneal tissue. Further studies are required to evaluate if diabetes-induced corneal collagen alterations can predict the development of diabetic retinopathy.

Laura Kowalczuk was supported by the “Agence Nationale de la Recherche”, ANR-08-TecSan-012 “NOUGAT.” Gaël Latour was supported by “RTRA-Triangle de la Physique” and “Fondation de France - Fondation Berthe Fouassier.” The work at LOB was supported by ANR-10-INBS-04.

Corneal changes in the posterior corneas of GK rats highlighted by in vivo CCM. (A–B) Frontal images of the endothelium, demonstrating signs of endothelial cell stresses, as hyper-reflective junctions in young GK rats (A) and cornea guttata (B) in old GK rats. (C–F) Frontal images of the DM, showing hyper-reflective dense deposits in corneal peripheries from both young (C) and old (D, F) GK rats. In old nondiabetic control rat, DM images showed no or sparse (E) hyper-reflective deposits. Scale bar, 100 μm.

Figure 4.

Corneal changes in the posterior corneas of GK rats highlighted by in vivo CCM. (A–B) Frontal images of the endothelium, demonstrating signs of endothelial cell stresses, as hyper-reflective junctions in young GK rats (A) and cornea guttata (B) in old GK rats. (C–F) Frontal images of the DM, showing hyper-reflective dense deposits in corneal peripheries from both young (C) and old (D, F) GK rats. In old nondiabetic control rat, DM images showed no or sparse (E) hyper-reflective deposits. Scale bar, 100 μm.

3D SHG view of the DM of the GK cornea No. 7 in false colors (200 × 200 × 9 μm3). Strong SHG signals are emitted by fibrillar collagen abnormalities, which allows their spatial characterization. Note that the fibrils in the foreground appear larger than in the background because of the 3D viewer.

Movie.

3D SHG view of the DM of the GK cornea No. 7 in false colors (200 × 200 × 9 μm3). Strong SHG signals are emitted by fibrillar collagen abnormalities, which allows their spatial characterization. Note that the fibrils in the foreground appear larger than in the background because of the 3D viewer.

Ex vivo SHG images in the DM of human corneas. (A–B) False color images of the corneas from nondiabetic donors, showing sparse SHG signals in corneal periphery of one hypertensive patient (B, in green; 20x objective). (C–F) False color images of the corneas from two diabetic donors, demonstrating the presence of SHG signals (in green) in the entire DM in the case of unbalanced diabetes (C–D; 60x objective) and only in the DM periphery in the case of balanced diabetes (E–F; 20x objective). Scale bar, 20 μm.

Figure 7.

Ex vivo SHG images in the DM of human corneas. (A–B) False color images of the corneas from nondiabetic donors, showing sparse SHG signals in corneal periphery of one hypertensive patient (B, in green; 20x objective). (C–F) False color images of the corneas from two diabetic donors, demonstrating the presence of SHG signals (in green) in the entire DM in the case of unbalanced diabetes (C–D; 60x objective) and only in the DM periphery in the case of balanced diabetes (E–F; 20x objective). Scale bar, 20 μm.